Erjun Liang

7.2k total citations
292 papers, 6.1k citations indexed

About

Erjun Liang is a scholar working on Materials Chemistry, Electrical and Electronic Engineering and Electronic, Optical and Magnetic Materials. According to data from OpenAlex, Erjun Liang has authored 292 papers receiving a total of 6.1k indexed citations (citations by other indexed papers that have themselves been cited), including 186 papers in Materials Chemistry, 130 papers in Electrical and Electronic Engineering and 78 papers in Electronic, Optical and Magnetic Materials. Recurrent topics in Erjun Liang's work include Thermal Expansion and Ionic Conductivity (138 papers), Microwave Dielectric Ceramics Synthesis (84 papers) and Ferroelectric and Piezoelectric Materials (62 papers). Erjun Liang is often cited by papers focused on Thermal Expansion and Ionic Conductivity (138 papers), Microwave Dielectric Ceramics Synthesis (84 papers) and Ferroelectric and Piezoelectric Materials (62 papers). Erjun Liang collaborates with scholars based in China, Italy and Germany. Erjun Liang's co-authors include Mingju Chao, Pei Ding, Junqiao Wang, Jinna He, Qilong Gao, Shi‐Lei Su, Chunzhen Fan, W. Kiefer, Qianzhong Xue and Qiang Sun and has published in prestigious journals such as Journal of the American Chemical Society, Physical Review Letters and Angewandte Chemie International Edition.

In The Last Decade

Erjun Liang

282 papers receiving 5.8k citations

Peers — A (Enhanced Table)

Peers by citation overlap · career bar shows stage (early→late) cites · hero ref

Name h Career Trend Papers Cites
Erjun Liang China 41 3.2k 2.3k 1.9k 1.3k 1.2k 292 6.1k
Huiqiu Deng China 45 4.5k 1.4× 2.0k 0.9× 640 0.3× 536 0.4× 1.1k 0.9× 380 7.9k
Roman Engel‐Herbert United States 34 3.2k 1.0× 2.7k 1.2× 1.4k 0.7× 618 0.5× 897 0.7× 121 5.6k
Ohad Levy United States 26 4.5k 1.4× 1.2k 0.5× 804 0.4× 725 0.6× 687 0.6× 56 6.0k
Wenjuan Zhu China 44 5.6k 1.7× 4.3k 1.9× 2.0k 1.1× 3.4k 2.6× 1.9k 1.6× 167 9.4k
Jie Li China 45 1.9k 0.6× 3.8k 1.7× 3.4k 1.8× 2.1k 1.6× 1.9k 1.6× 346 7.8k
Peter J. Klar Germany 42 3.7k 1.2× 3.7k 1.6× 1.5k 0.8× 852 0.7× 2.3k 1.9× 315 7.4k
Albina Y. Borisevich United States 53 6.6k 2.0× 2.9k 1.3× 3.2k 1.7× 1.3k 1.0× 909 0.8× 188 9.3k
Gang Zhao China 47 2.4k 0.7× 3.5k 1.5× 1.2k 0.6× 638 0.5× 999 0.8× 205 5.8k
Hongxing Dong China 32 1.4k 0.4× 1.7k 0.7× 937 0.5× 667 0.5× 1.0k 0.9× 129 3.5k
Jing Wu China 44 4.8k 1.5× 3.0k 1.3× 1.1k 0.6× 1.1k 0.9× 737 0.6× 184 6.7k

Countries citing papers authored by Erjun Liang

Since Specialization
Citations

This map shows the geographic impact of Erjun Liang's research. It shows the number of citations coming from papers published by authors working in each country. You can also color the map by specialization and compare the number of citations received by Erjun Liang with the expected number of citations based on a country's size and research output (numbers larger than one mean the country cites Erjun Liang more than expected).

Fields of papers citing papers by Erjun Liang

Since Specialization
Physical SciencesHealth SciencesLife SciencesSocial Sciences

This network shows the impact of papers produced by Erjun Liang. Nodes represent research fields, and links connect fields that are likely to share authors. Colored nodes show fields that tend to cite the papers produced by Erjun Liang. The network helps show where Erjun Liang may publish in the future.

Co-authorship network of co-authors of Erjun Liang

This figure shows the co-authorship network connecting the top 25 collaborators of Erjun Liang. A scholar is included among the top collaborators of Erjun Liang based on the total number of citations received by their joint publications. Widths of edges represent the number of papers authors have co-authored together. Node borders signify the number of papers an author published with Erjun Liang. Erjun Liang is excluded from the visualization to improve readability, since they are connected to all nodes in the network.

All Works

20 of 20 papers shown
1.
Yuan, Huanli, Kaiyue Zhao, Yuanbing Mao, et al.. (2025). Low-frequency phonon driven enhancement of negative thermal expansion in Zn2−xMnxGeO4. Tungsten. 8(1). 182–195. 1 indexed citations
2.
Chen, Xin, Qilong Gao, Kaiyue Zhao, et al.. (2025). Predicting thermal expansion in framework compounds using a charge interaction index. Chemical Science. 16(35). 16331–16338.
3.
Wang, Qingjie, Yongqiang Qiao, Kaiyue Zhao, et al.. (2024). Zero thermal expansion in K Mn In2-(MoO4)3 based materials. Acta Materialia. 281. 120358–120358. 5 indexed citations
4.
Shen, Ruofan, Yanyan Liu, Shilin Liu, et al.. (2024). Symmetry-broken atomic ensemble induced by mandated charge for efficient water dissociation in hydrogen generation. Journal of Energy Chemistry. 103. 274–281. 5 indexed citations
5.
Guo, Juan, et al.. (2024). Enhanced electrochromic performance of K WO3 by tailoring crystal structure and valence state. Solid State Ionics. 414. 116632–116632. 1 indexed citations
6.
Yang, Mengjie, Wenjing Wang, Wenyue Sun, et al.. (2024). Influence of Sn on thermal expansion and dielectric properties of ZrMgMo3O12. Ceramics International. 50(16). 28177–28185. 2 indexed citations
7.
Qiao, Yongqiang, et al.. (2024). Tunable thermal expansion via the magnetic phase competition in kagome magnets. Applied Physics Letters. 125(3). 8 indexed citations
8.
Wang, Junping, Qingdong Chen, Yanjun Ji, & Erjun Liang. (2023). Low thermal expansion and weak hygroscopicity of Y2-xZrxMo3-xPxO12. Ceramics International. 50(2). 4213–4217. 1 indexed citations
9.
Wang, Mengyue, Xiansheng Liu, Feng Zhang, et al.. (2023). High configurational entropy for low phase transition temperature and thermal expansion of A2M3O12 oxide ceramics. Ceramics International. 49(20). 33051–33056. 4 indexed citations
10.
Guo, Juan, et al.. (2023). Zero thermal expansion in Cs2W3O10. Chinese Chemical Letters. 35(7). 108957–108957. 2 indexed citations
11.
Shen, Ruofan, Yanyan Liu, Huanhuan Zhang, et al.. (2023). Coupling oxygen vacancy and hetero-phase junction for boosting catalytic activity of Pd toward hydrogen generation. Applied Catalysis B: Environmental. 328. 122484–122484. 45 indexed citations
12.
Xi, Zhen, Andrea Sanson, Qiang Sun, Erjun Liang, & Qilong Gao. (2023). Role of alkali ions in the near-zero thermal expansion of NaSICON-type AZr2(PO4)3 (A=Na,K,Rb,Cs) and Zr2(PO4)3 compounds. Physical review. B.. 108(14). 20 indexed citations
13.
Wen, Hao, Ruofan Shen, Yanyan Liu, et al.. (2023). Insights into boosting catalytic hydrogen evolution over Co doping Ru nanoparticles. Fuel. 351. 128950–128950. 14 indexed citations
14.
Zheng, Yi, Yongqiang Qiao, Andrea Sanson, et al.. (2023). Control of Thermal Expansion in TaVO5 by Double Chemical Substitution. Inorganic Chemistry. 62(22). 8543–8550. 1 indexed citations
15.
Ding, Xingxing, et al.. (2023). Synthesis of Co9S8@CNT hydrogen production composites by one-step pyrolysis of monomolecule precursor. APL Materials. 11(6). 1 indexed citations
16.
Wu, Yanan, Junqiao Wang, Ran Li, et al.. (2019). Double-wavelength nanolaser based on strong coupling of localized and propagating surface plasmon. Journal of Physics D Applied Physics. 53(13). 135108–135108. 26 indexed citations
17.
Mao, Yanchao, Chuan Ning, Yue Hu, et al.. (2018). Enhancing Photoelectrochemical Performance of TiO2 Nanowires through a Facile Acid Treatment Method. Journal of The Electrochemical Society. 165(13). H799–H803. 17 indexed citations
18.
Song, Wenbo, Baohe Yuan, Xiansheng Liu, et al.. (2014). Tuning the monoclinic-to-orthorhombic phase transition temperature of Fe2Mo3O12by substitutional co-incorporation of Zr4+and Mg2+. Journal of materials research/Pratt's guide to venture capital sources. 29(7). 849–855. 17 indexed citations
19.
20.
Liang, Erjun, et al.. (2004). Synthesis and correlation study on the morphology and Raman spectra of CNx nanotubes by thermal decomposition of ferrocene/ethylenediamine. Diamond and Related Materials. 13(1). 69–73. 36 indexed citations

Rankless uses publication and citation data sourced from OpenAlex, an open and comprehensive bibliographic database. While OpenAlex provides broad and valuable coverage of the global research landscape, it—like all bibliographic datasets—has inherent limitations. These include incomplete records, variations in author disambiguation, differences in journal indexing, and delays in data updates. As a result, some metrics and network relationships displayed in Rankless may not fully capture the entirety of a scholar's output or impact.

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